CZ307194B6 - A torque tool for tightening or loosening joints and a method of tightening or loosening joints - Google Patents

Abstract

A torque tool for tightening or loosening connections has a driving element engageable with a turnable part of the connection for turning the turnable part of the connection for tightening or loosening the connection and turnable about an axis, and a power drive configured for acting on the driving element such that the drive acts on the driving element to turn the driving element and thereby to turn the turnable part of the connection over a partial stroke and a space is formed between the drive and the driving element, and the drive is then displaced over the space toward the driving element to act again on the driving element to turn the driving element and thereby to further turn the turnable part of the connection over a further partial stroke.

Description

Technical field

The invention relates to a torque tool for tightening or loosening joints and a method of tightening or loosening joints.

BACKGROUND OF THE INVENTION

According to the prior art, the tightening and loosening of joints, such as on gas turbines or gas pipes, is generally carried out using hand wrenches. Typically, two wrenches are used, one to hold the tightened area in place, and the other to use to tighten or loosen the screw.

Normally, the force that can be exerted with a conventional wrench is insufficient to either tighten or loosen the industrial screw. In addition, such screw connections are often inaccessible or surrounded by other industrial equipment such as pipes, meters, electrical connections and the like. Such connections and pipes in the vicinity make it difficult to safely handle the hand keys in the immediate vicinity.

Moreover, it is often the case that, with respect to the surrounding device and the like, it is not possible to manipulate the hand wrench in the vicinity of the screw to be rotated. In such situations, it is necessary to extend the length of the hand wrench by putting on it a piece of pipe that surrounds the handle of the wrench and lengthens it more efficiently.

Therefore, in a typical prior art application, it is sometimes necessary to handle two hand wrenches, each extending through a piece of pipe so that the wrenches extend beyond the surrounding area to tighten and loosen the screw.

Such a method is both difficult and tedious as well as potentially dangerous in terms of possible damage to surrounding equipment such as pipes or electrical connections or the like.

It is therefore considered clear and appropriate to provide an approved tool for tightening and loosening such joints and method.

Accordingly, it is an object of the invention to provide a method of tightening or loosening joints and a torque tool for tightening or loosening joints that avoid the disadvantages of the prior art.

SUMMARY OF THE INVENTION

Said shortcomings of the prior art are overcome by a torque tightening or loosening tool comprising a drive member that is rotatable about an axis and adapted to engage, rotate to tighten or loosen the joint, and a power drive adapted to rotate the drive member and thereby rotating the pivoting portion of the coupling in a partial stroke to form a space between the power drive and the drive member, wherein the power drive is further adapted to subsequently move over the created space towards the drive member to further rotate and thereby rotate the pivoting portion of the coupling in the next partial stroke; further comprising a reaction element which is adapted to engage the non-rotatable portion of the joint and is configured to exert a resistance generated during rotation of the rotatable portion of the joint by the rotation of the drive member by means of a power drive, eotočná část

And said reaction element are arranged such that during rotation of the rotatable portion of the joint by the drive member, said non-rotatable portion of the joint and the reactive element are non-rotatable relative to each other, while the non-rotatable portion of the joint moves relative to to the reaction element by the action of the latch mechanism.

It is furthermore provided that the power drive is configured as a hydraulically actuated drive consisting of a cylinder and a movably mounted piston with a piston rod which is adapted to act on the drive member to rotate it and thereby rotate with a partial stroke of the rotatable part of the joint and to reciprocate to the starting position.

It is also a feature that the torque tool comprises a stationary part formed by a cylinder as parts of a power drive attached to the side plates against which the drive member is rotatably mounted, or that the stationary part and the reaction element are arranged to fix relative to each other and for moving the stationary portion relative to the reaction element by means of a latch mechanism as the drive moves to the drive member.

It can also be seen that a retaining pawl is mounted on one of the stationary portions and the reaction element as one portion of the latch mechanism, and the toothing is provided on the other of the stationary portions and the reaction element for engagement with each other thereby holding the stationary portion and the reaction element. mutually immovably during rotation of the drive member by the power drive and free movement of the retaining pawl over the toothing when the drive is moved to the drive member (16), or that the reaction element is detachably connected to the stationary parts and mountable alternately on one axial side of the stationary or on the other side of the stationary part.

It is also essential that the stationary part comprises a member that is part of the power drive and a member to which the drive member is movable, said drive member and stationary part being provided with means for rotatably guiding said drive member relative to the stationary part, said means comprising an interacting first projection and a first groove for engaging and reciprocating one another with an axis about the axis, as well as that the stationary portion and the reaction element have means for rotatably guiding the stationary portion relative to the reaction element, the other around the axis.

Said drawbacks of the prior art are also overcome by a method of tightening or loosening the joints with a torque tool, which comprises engaging a drive member with a rotatable part of the joint to rotate it to tighten or loosen the joint about an axis. rotating and hence rotating the pivotal portion of the joint in the partial stroke to create a space between the power drive and the drive member, the power drive shifting through this space toward the drive member and again applying a power drive to the drive member to rotate it and thereby rotating the rotary the reaction element is engaged with the non-rotatable part of the joint, and when the drive member is rotated by a power drive and the rotatable part of the joint is rotated, the reaction element counteracts the reaction force generated during rotation of the rotatable part of the joint; the stationary portion and the reaction element act such that when the rotatable portion of the coupling is rotated by the drive member, the stationary portion does not move relative to the reaction element, while during the displacement of the drive member over space, the stationary portion moves relative to the reaction element through the retaining latch mechanism.

The method further comprises the use of a power drive as a hydraulically actuated drive comprising a cylinder and a piston with a piston rod that moves within the cylinder, while pulling the piston rod out of the cylinder acting on the drive member so as to rotate thereby rotating the rotary joint over the partial stroke, the cylinder is displaced over the space toward the drive member, the piston rod extends again from the cylinder towards the actuator, the drive member rotates again, and thereby rotates the rotary joint over the next partial stroke and that the stationary portion does not move during rotation of the drive member and that an element that is part of the power drive and an element against which the drive member rotates is integrated into the stationary part.

-2GB 307194 B6

Furthermore, the essence of the method is that when the drive member is rotated by the rotary part of the joint by means of a power drive, the reaction element and the stationary part are immovable relative to each other by the latch mechanism, but rotate when the power drive is moved to the drive member.

An essential feature of the method is also that the latch mechanism is provided as a retaining pawl mounted on one of the stationary portions and the reaction element, and by toothing on the other of the stationary portions and the reaction element, wherein the retaining pawl engages the teeth and retains the stationary portion and the reaction element non-rotatable relative to each other when the power drive rotates the drive member, but allows the retaining pawl to jump the teeth of the toothing when the power drive moves toward the drive member, as well as the reaction element being reciprocally coupled to the stationary part so as to be mounted alternately on one axial on the side of the stationary part or on the other axial side of the stationary part.

And last but not least, the principle of engaging a pivot member with a rotating portion of the coupling to rotate it to tighten or loosen the joint about an axis, exerts a force drive on the pivot member to rotate it and thereby rotate the rotatable portion of the joint in a partial stroke. and a space is formed between the power drive and the drive member, the power drive is moved through this space towards the drive member and re-applied by force drive to the drive member to rotate it and further rotate the rotary part of the joint for another partial stroke; engaging with the non-rotatable portion of the joint, wherein when the drive member is rotated by a power drive and the rotatable portion of the joint is rotated, the reaction element counteracts the reaction force generated during the rotatable portion of the joint; the drive member and the stationary part drive member having means for rotating relative to each other, said means comprising an interacting first projection and a first groove for engaging one another and moving relative to one another axis.

Clarification of drawings

An exemplary embodiment of a torque tool for tightening or loosening joints and a method of tightening or loosening joints according to the invention is shown in the accompanying drawings, in which: Fig. 1 is a simplified pipe fitting to be tightened or loosened; Fig. 3 is a schematic view of the torque tool as used for tightening or loosening the pipe fitting; Figs. 5a and 5b are side views; and Figs. 6a and 6b the side views and the end of the torque tool drive plate; FIGS. 7a and 7b the side views and the end of the torque tool reaction plate; and FIGS. 8a and 8b the side views. and the end of the torque tool holding pawl.

DETAILED DESCRIPTION OF THE INVENTION

The method of tightening and loosening the joints and the torque tool for tightening and loosening the joints according to the invention can be used, for example, to tighten or loosen the pipe fitting 1 shown in Fig. 1. The pipe joint 1 has a tubular part 2 provided with a non-rotatable, shaped part As the hexagonal portion forming the non-rotatable portion of the joint 3 and the head 4 provided with an external thread 5. The nut, i.e. the rotatable portion of the joint 6 having an internal thread 7, must be tightened on the head 4 by rotating it.

The torque tool according to the invention is provided with a power drive 11 and can be designed as a hydraulic drive comprising a cylinder 12 and a piston 13 with a piston rod 14 movable in the cylinder 12.

-3 CZ 307194 B6

The power drive 11 is immovably connected to the two side plates 15. The power drive cylinder 12 and the side plates 15 together form a stationary part of the torque tool which does not rotate during rotation of the rotary part 6 of the coupling 1.

The torque tool drive element is formed, for example, by a drive member 16 which is positioned between the side plates 15 and is rotatable about axis A by the piston rod 14 of the power drive 11 which transmits the motive force to the drive member 16 when the piston rod 14 is ejected from the power drive cylinder 12 11.

The torque tool further has a reaction element Γ7 which is connectable to the non-rotatable part 3 of the joint 1 to counteract the reaction force that is generated during rotation of the rotary part 6 of the joint 1 by the drive member 16 to prevent the tool from rotating back while the rotary part 6 rotates forward. The reaction element 17 is formed, for example, as a reaction plate which cooperates with the retaining pawl 18. The retaining pawl 18 is rotatably mounted on a stationary portion of the torque tool. For example, one such retaining pawl 18 is mounted on each side plate 15. Each retaining pawl 18 is urged by a spring 19 toward the reaction element 17.

As shown in Figures 5a and 5b, each side plate 15 has a first groove 21 that is formed on one side of the side plate 15 and extends circumferentially at an angle about an axis A. A correspondingly shaped first projection 22 of the drive member 16 is slidably mounted in the first groove 21 of the side plate 15.

The side plate 15 further has a second projection 23 provided on the opposite side and extending circumferentially about the axis A. The second projection 23 of the side plate 15 is slidably mounted in a corresponding second groove 24 formed in the reaction element 17. The side plates 15 are immovably connected to the force a drive 11, for example a notch 25 formed in each side plate 15 and a protrusion 26 formed on the power drive 11.

The drive member 16 has a protruding portion 27 cooperating with the piston rod 14 of the power drive 11 to rotate the drive member 16 during the working stroke of the tool. It also has an engagement portion 28, which is formed as a polygonal sleeve, on the other side. It is designed, for example, as a 12-point collar. The engagement portion 28 with its polygonal sleeve engages the rotatable portion 6 of the joint to be tightened or released.

The reaction element 17 has a polygonal portion 29 provided with an inner polygonal sleeve, formed, for example, as a substantially hexagonal sleeve with edges. During operation, the polygonal portion 29 provided with the inner polygonal sleeve is positioned by this receptacle on the hexagonal non-rotatable portion 3 of the reaction joint 1 as explained above.

At the outer edge of the reaction element 17, there are two sets of formations, for example, formed as an inclined toothing 30 'and 30. The retaining pawl 18 has a retaining portion 31 capable of engaging the toothing 30' or 30 to hold the reaction element 17 so as to that it does not rotate during the working stroke of the torque tool and that it latches over the teeth 30 ', 30 of the reaction element 17 during the non-working stroke of the torque tool.

The two retaining pawls 18, located on opposite axial sides, may be pivotally connected to the side plates 15, for example a pin, which passes through holes formed in the retaining pawls 18 and the side plates 15 and which are aligned.

The torque tool further has a fluid supply system 32 that serves for a hydraulically actuated power drive 11

The torque tool for tightening or loosening the joints according to the invention operates in the following manner by tightening or loosening the joints.

-4GB 307194 B6

When it is necessary to rotate the rotatable portion 6 of the joint 1, for example, to tighten the nut on the head 4 of the joint 1 in the form of a pipe fitting, the fluid is supplied to the hydraulically actuated power drive 11. on the drive member 16 by applying a force, for example, by pushing on the drive member 16 and rotating the drive member 16 such that it, with its third protrusion 26, rotates the rotatable portion 6 of the connection 6;

During rotation of the drive member 16, the retaining pawl 18 is mounted on the stationary tool part, for example on the side plate 15, in engagement with the corresponding toothing 30 ', 30 of the reaction element 17 so that the reaction force generated during rotation is transmitted via the side plate 15 of the retaining pawl 8 and the reaction element 17 to the non-rotatable portion 3 of the joint 1 to prevent rotation of the torque tool in the opposite direction.

The drive member 16, and correspondingly the pivot part 6 of the joint 1, perform a partial stroke and the pivot part 6 rotates at a predetermined angle, for example 20 to 30 °. In order to rotate the rotating part 6 further, the stationary part of the tool, for example the cylinder 12 of the power drive 11 and the side plate 15, moves towards the drive member 66. During this displacement, the retaining pawl 18 jumps over the corresponding teeth 30 ', 30 of the reaction element 17.

Thereafter, the power drive 11 is reactivated and the piston rod 14 slides out of the cylinder 12 so that it acts on the drive member 16 again and rotates them over the next angle at the next stroke. During this phase, the same process takes place, namely that the movement force exerted by the force drive 11 is transmitted by the drive member 16 to the rotatable part 6 of the connection 6 while the reaction force is transmitted through the side plate 15, holding latch 18 and reaction element 17 to non-rotatable. part 3 of the connection £

The reaction element 17 is removable of the corresponding side plate 15. It may be located on one axial side of the side plate 15, for example, to tighten the joint as shown in Fig. 4. It may then be removed and placed on the opposite side of the side plates 15, e.g. for loosening joints. While in the first position the retaining pawl 18 interacts with one set of gears, for example the toothing 30 'of the reaction element 17, in the second position when the reaction element 17 is located on the opposite side of the side plates 15, the retaining pawl 18 cooperates with another set of gears. by the toothing 30 of the reaction element 47. The teeth 30 'and 30 may be inclined to hold the reaction element 17 by the latch 18 during rotation of the rotatable portion 6 of the joint 1 and to allow the latch 8 to jump over the teeth 30' and 30 during the movement of the side drive plate 12. 15 toward the drive member 16.

Industrial applicability

When the method of tightening or loosening the joints is performed according to the present invention and the torque tool for tightening or loosening the joints is constructed according to the invention, it enables reliable, safe and efficient tightening or loosening of the respective joints such as gas pipe or gas turbine joints and the like.

It will be understood that each of the elements described above, or two or more of them together, may find useful applications in other types of structures that differ from those described above.

While the invention is illustrated and described as an embodiment of a torque tool for tightening or releasing a joint, as well as a method of tightening or releasing a joint, it is not limited to the details shown, but many modifications and design changes are possible within the general idea of the invention.

-5GB 307194 B6

The foregoing fully describes the idea of the present invention that it is thereby possible for other persons without further analysis, using routine knowledge, to readily adapt it to a variety of uses while maintaining the essential features of the invention over the prior art.

Claims (15)

A torque tool for tightening or loosening joints, comprising a drive member (16) that is rotatable about an axis (A) and adapted to engage a rotatable portion (6) of the joint (1) to rotate it to tighten or loosen a joint (1) and a power drive (11) adapted to rotate the drive member (16) and thereby rotate the rotatable portion (6) of the coupling (1) in a partial stroke to form a space between the power drive (11) and the drive member (16), the power drive (11) is further adapted to be subsequently displaced over the space formed towards the drive member (16) to further rotate and thereby further rotate the rotatable portion (6) of the joint (1) in a further partial stroke and further comprising a reaction element ( 17), which is adapted to engage the non-rotatable portion (3) of the joint (1) and is arranged to generate a resistance generated during rotation of the rotatable portion (6) of the joint (1) due to rotation of the drive member (16) by 11. A non-rotatable part (3) and said reaction element (17) are arranged such that during rotation of the rotatable part (6) of the coupling by the drive member (16) said non-rotatable part (3) and the reaction The element (17) is non-rotatable relative to one another, while during movement of the drive (11) to the drive member (16) over the gap, the non-rotatable portion (3) of the joint moves relative to the reaction element (17) by the latching mechanism. Torque tool according to claim 1, characterized in that the power drive (11) is arranged as a hydraulically actuated drive consisting of a cylinder (12) and a movably mounted piston (13) with a piston rod (14) adapted to act on the drive member (16) to rotate it and thereby rotate the partial stroke of the rotatable part (6) of the joint (1) and to return it back to its starting position. Torque tool according to claim 1, characterized in that it comprises a stationary part formed by a cylinder (12) as parts of a power drive (11) attached to the side plates (15), against which the drive member (16) is rotatably mounted. Torque tool according to claim 1, characterized in that the stationary part and the reaction element (17) are arranged to fix the relative position when the rotary part (6) of the coupling (1) is rotated by the drive member (16) and to move the stationary part relative to the reaction part. element (17) by a latch mechanism when the drive (11) is moved to the drive member (16). Torque tool according to claim 4, characterized in that a retaining pawl (18) is mounted on one of the stationary part and the reaction element (17) as one part of the pawl mechanism, and the toothing (30 ', 30) is provided on the other of of the stationary part and reaction element (17), for engagement with each other and thereby to hold the stationary part and reaction element (17) immovably relative to each other during rotation of the drive member (16) by a power drive (11) and free movement of the retaining pawl (18) over the teeth , 30) when the power drive (11) is moved to the drive member (16). A torque tool according to claim 1, characterized in that the reaction element (17) is detachably connected to the stationary part and is mountable alternately on one axial side of the stationary part or on the other axial side of the stationary part. Torque tool according to any one of the preceding claims 3 to 6, characterized in that the stationary part comprises a member which is part of the power drive (11) and a member to which it is driven. The movable member (16), said drive member (16) and the stationary portion being provided with means for rotatably guiding said drive member (16) relative to the stationary portion, said means comprising an interacting first projection (22) and a first member (16). a groove (21) for engagement and relative displacement of one another with the other around the axis (A). Torque tool according to any one of the preceding claims 3 to 7, characterized in that the stationary part and the reaction element (17) have means for rotatably guiding the stationary part relative to the reaction element (17), comprising a second projection (23) and a second groove. (24) sliding relative to one another about the axis (A). Method for tightening or loosening joints with a torque tool according to the preceding claims 1 to 8, characterized in that a drive member (16) is engaged with a rotatable part (6) of the joint (1) to rotate it for tightening or loosening the joint (1). ) around the axis (A), acting with the power drive (11) on the drive member (16) to rotate it and thereby rotate the rotatable part (6) of the coupling (1) in the partial stroke, creating space between the power drive (11) and the drive member (16), the power drive (11) is moved through this space towards the drive member (16) and is again applied by the power drive (11) to the drive member (16) to rotate it and thereby further rotate the rotatable coupling part (6) (1) by another partial stroke, the reaction element (17) engages with the non-rotatable part (3) of the coupling (1), while rotating the drive member (16) by means of a power drive (11) and rotating the rotatable part (6) of the coupling (1) the reaction element (17) acts pr oti the reaction force generated during rotation of the rotatable portion (6) of the joint (1), and further adapting the stationary portion and reaction element (17) such that when the rotatable portion (6) of the joint (1) is driven by the drive member (16) relative to the reaction element (17) does not move, while during the displacement of the drive member (16) over the space, the stationary portion moves relative to the reaction element (17) by the retaining latch mechanism. The method of claim 9, further comprising providing a power drive (11) as a hydraulic actuator comprising a cylinder (12) and a piston (13) with a piston rod (14) that moves within the cylinder (12), wherein the piston rod (14) extends from the cylinder (12) acting on the drive member (16) so as to rotate, thereby rotating the rotatable part (6) of the coupling (1) over the partial stroke, the cylinder (12) is moved over the space towards the drive member (16), the piston rod (14) is ejected from the cylinder (12) towards the drive member (16) again, the drive member (16) rotates again and thereby rotates with the rotary part ( 6) joints (1) via another partial stroke. Method according to claim 9, characterized in that the stationary part does not move during the rotation of the drive member (16) and that an element which is part of the power drive (11) and an element with which the drive member is integrated into the stationary part (16) rotates. Method according to claim 11, characterized in that, when the drive member (16) is rotated by the rotary part (6) of the connection (1) by means of a power drive (11), the reaction element (17) and the stationary part are immovable relative to each other , but rotates when the power drive (11) is moved to the drive member (16). Method according to claim 12, characterized in that the latch mechanism is provided as a retaining pawl (18) mounted on one of the stationary portions and the reaction element (17), and by a toothing (30 ', 30) on the other of the stationary portions and the reaction element (17), wherein the retaining pawl (18) engages the toothing (30 ', 30) and holds the stationary portion and reaction element (17) non-rotatable relative to each other when the power drive (11) rotates the drive member (16) but a gear latch (30 ', 30) as the power drive (11) moves towards the drive member (16). Method according to claim 9, characterized in that the reaction element (17) is reversibly connected to the stationary part so that it is mountable alternately on one axial side of the stationary part or on the other axial side of the stationary part. -7EN 307194 B6 Method for tightening or loosening joints with a torque tool according to the preceding claims 1 to 8, characterized in that a drive member (16) is engaged with a rotatable part (6) of the joint (1) to rotate it for tightening or loosening the joint (1). around the axis (A), acting on the drive member (16) to rotate it and thereby rotate the rotatable part (6) of the coupling (1) with a power drive (11), in a partial stroke, creating space between the power drive (11) and by the drive member (16), the power drive (11) is moved through this space towards the drive member (16) and again applied by the power drive (11) to the drive member (16) to rotate it and thereby further rotate the rotary part (6) of the coupling (1) by another partial stroke, the reaction element (17) engages with the non-rotatable part (3) of the coupling (1), wherein when the drive member (16) is rotated by a power drive (11) and the rotatable part (6) of the joint (1) the reaction element (17) acts against the reaction force generated during rotation of the rotatable portion (6) of the coupling (1), wherein the stationary portion does not rotate during rotation of the drive member (16), wherein the stationary portion comprises an element which is part of the power drive (11) and the drive member (16) drives, and the stationary part drive member (16) has means for rotating one another relative to each other, said means comprising an interacting first projection (22) and a first groove (21) for engaging one another and the other displacement around the axis (A).